///////////////////////////////////////////////////////////////////////////////
// \author (c) Marco Paland (info@paland.com)
//             2014-2019, PALANDesign Hannover, Germany
//
// \license The MIT License (MIT)
//
// Permission is hereby granted, free of charge, to any person obtaining a copy
// of this software and associated documentation files (the "Software"), to deal
// in the Software without restriction, including without limitation the rights
// to use, copy, modify, merge, publish, distribute, sublicense, and/or sell
// copies of the Software, and to permit persons to whom the Software is
// furnished to do so, subject to the following conditions:
//
// The above copyright notice and this permission notice shall be included in
// all copies or substantial portions of the Software.
//
// THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
// IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
// FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
// AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
// LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
// OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN
// THE SOFTWARE.
//
// \brief Tiny printf, sprintf and (v)snprintf implementation, optimized for speed on
//        embedded systems with a very limited resources. These routines are thread
//        safe and reentrant!
//        Use this instead of the bloated standard/newlib printf cause these use
//        malloc for printf (and may not be thread safe).
//
///////////////////////////////////////////////////////////////////////////////

#include <stdbool.h>
#include <stdint.h>

#include "printf.h"

// define this globally (e.g. gcc -DPRINTF_INCLUDE_CONFIG_H ...) to include the
// printf_config.h header file
// default: undefined
#ifdef PRINTF_INCLUDE_CONFIG_H
#include "printf_config.h"
#endif

// 'ntoa' conversion buffer size, this must be big enough to hold one converted
// numeric number including padded zeros (dynamically created on stack)
// default: 32 byte
#ifndef PRINTF_NTOA_BUFFER_SIZE
#define PRINTF_NTOA_BUFFER_SIZE 32U
#endif

// 'ftoa' conversion buffer size, this must be big enough to hold one converted
// float number including padded zeros (dynamically created on stack)
// default: 32 byte
#ifndef PRINTF_FTOA_BUFFER_SIZE
#define PRINTF_FTOA_BUFFER_SIZE 32U
#endif

// support for the floating point type (%f)
// default: activated
#ifndef PRINTF_DISABLE_SUPPORT_FLOAT
#define PRINTF_SUPPORT_FLOAT
#endif

// support for exponential floating point notation (%e/%g)
// default: activated
#ifndef PRINTF_DISABLE_SUPPORT_EXPONENTIAL
#define PRINTF_SUPPORT_EXPONENTIAL
#endif

// define the default floating point precision
// default: 6 digits
#ifndef PRINTF_DEFAULT_FLOAT_PRECISION
#define PRINTF_DEFAULT_FLOAT_PRECISION 6U
#endif

// define the largest float suitable to print with %f
// default: 1e9
#ifndef PRINTF_MAX_FLOAT
#define PRINTF_MAX_FLOAT 1e9
#endif

// support for the long long types (%llu or %p)
// default: activated
#ifndef PRINTF_DISABLE_SUPPORT_LONG_LONG
#define PRINTF_SUPPORT_LONG_LONG
#endif

// support for the ptrdiff_t type (%t)
// ptrdiff_t is normally defined in <stddef.h> as long or long long type
// default: activated
#ifndef PRINTF_DISABLE_SUPPORT_PTRDIFF_T
#define PRINTF_SUPPORT_PTRDIFF_T
#endif

///////////////////////////////////////////////////////////////////////////////

// internal flag definitions
#define FLAGS_ZEROPAD (1U << 0U)
#define FLAGS_LEFT (1U << 1U)
#define FLAGS_PLUS (1U << 2U)
#define FLAGS_SPACE (1U << 3U)
#define FLAGS_HASH (1U << 4U)
#define FLAGS_UPPERCASE (1U << 5U)
#define FLAGS_CHAR (1U << 6U)
#define FLAGS_SHORT (1U << 7U)
#define FLAGS_LONG (1U << 8U)
#define FLAGS_LONG_LONG (1U << 9U)
#define FLAGS_PRECISION (1U << 10U)
#define FLAGS_ADAPT_EXP (1U << 11U)

// import float.h for DBL_MAX
#if defined(PRINTF_SUPPORT_FLOAT)
#include <float.h>
#endif

// output function type
typedef void (*out_fct_type)(char character, void* buffer, size_t idx, size_t maxlen);

// wrapper (used as buffer) for output function type
typedef struct
{
	void (*fct)(char character, void* arg);
	void* arg;
} out_fct_wrap_type;

// internal buffer output
static inline void _out_buffer(char character, void* buffer, size_t idx, size_t maxlen)
{
	if(idx < maxlen)
	{
		((char*)buffer)[idx] = character;
	}
}

// internal null output
static inline void _out_null(char character, void* buffer, size_t idx, size_t maxlen)
{
	(void)character;
	(void)buffer;
	(void)idx;
	(void)maxlen;
}

// internal _putchar wrapper
static inline void _out_char(char character, void* buffer, size_t idx, size_t maxlen)
{
	(void)buffer;
	(void)idx;
	(void)maxlen;
	if(character)
	{
		_putchar(character);
	}
}

// internal output function wrapper
static inline void _out_fct(char character, void* buffer, size_t idx, size_t maxlen)
{
	(void)idx;
	(void)maxlen;
	if(character)
	{
		// buffer is the output fct pointer
		((out_fct_wrap_type*)buffer)->fct(character, ((out_fct_wrap_type*)buffer)->arg);
	}
}

// internal secure strlen
// \return The length of the string (excluding the terminating 0) limited by 'maxsize'
static inline unsigned int _strnlen_s(const char* str, size_t maxsize)
{
	const char* s;
	for(s = str; *s && maxsize--; ++s)
		;
	return (unsigned int)(s - str);
}

// internal test if char is a digit (0-9)
// \return true if char is a digit
static inline bool _is_digit(char ch)
{
	return (ch >= '0') && (ch <= '9');
}

// internal ASCII string to unsigned int conversion
static unsigned int _atoi(const char** str)
{
	unsigned int i = 0U;
	while(_is_digit(**str))
	{
		i = i * 10U + (unsigned int)(*((*str)++) - '0');
	}
	return i;
}

// output the specified string in reverse, taking care of any zero-padding
static size_t _out_rev(out_fct_type out, char* buffer, size_t idx, size_t maxlen, const char* buf,
					   size_t len, unsigned int width, unsigned int flags)
{
	const size_t start_idx = idx;

	// pad spaces up to given width
	if(!(flags & FLAGS_LEFT) && !(flags & FLAGS_ZEROPAD))
	{
		for(size_t i = len; i < width; i++)
		{
			out(' ', buffer, idx++, maxlen);
		}
	}

	// reverse string
	while(len)
	{
		out(buf[--len], buffer, idx++, maxlen);
	}

	// append pad spaces up to given width
	if(flags & FLAGS_LEFT)
	{
		while(idx - start_idx < width)
		{
			out(' ', buffer, idx++, maxlen);
		}
	}

	return idx;
}

// internal itoa format
static size_t _ntoa_format(out_fct_type out, char* buffer, size_t idx, size_t maxlen, char* buf,
						   size_t len, bool negative, unsigned int base, unsigned int prec,
						   unsigned int width, unsigned int flags)
{
	// pad leading zeros
	if(!(flags & FLAGS_LEFT))
	{
		if(width && (flags & FLAGS_ZEROPAD) && (negative || (flags & (FLAGS_PLUS | FLAGS_SPACE))))
		{
			width--;
		}
		while((len < prec) && (len < PRINTF_NTOA_BUFFER_SIZE))
		{
			buf[len++] = '0';
		}
		while((flags & FLAGS_ZEROPAD) && (len < width) && (len < PRINTF_NTOA_BUFFER_SIZE))
		{
			buf[len++] = '0';
		}
	}

	// handle hash
	if(flags & FLAGS_HASH)
	{
		if(!(flags & FLAGS_PRECISION) && len && ((len == prec) || (len == width)))
		{
			len--;
			if(len && (base == 16U))
			{
				len--;
			}
		}
		if((base == 16U) && !(flags & FLAGS_UPPERCASE) && (len < PRINTF_NTOA_BUFFER_SIZE))
		{
			buf[len++] = 'x';
		}
		else if((base == 16U) && (flags & FLAGS_UPPERCASE) && (len < PRINTF_NTOA_BUFFER_SIZE))
		{
			buf[len++] = 'X';
		}
		else if((base == 2U) && (len < PRINTF_NTOA_BUFFER_SIZE))
		{
			buf[len++] = 'b';
		}
		if(len < PRINTF_NTOA_BUFFER_SIZE)
		{
			buf[len++] = '0';
		}
	}

	if(len < PRINTF_NTOA_BUFFER_SIZE)
	{
		if(negative)
		{
			buf[len++] = '-';
		}
		else if(flags & FLAGS_PLUS)
		{
			buf[len++] = '+'; // ignore the space if the '+' exists
		}
		else if(flags & FLAGS_SPACE)
		{
			buf[len++] = ' ';
		}
	}

	return _out_rev(out, buffer, idx, maxlen, buf, len, width, flags);
}

// internal itoa for 'long' type
static size_t _ntoa_long(out_fct_type out, char* buffer, size_t idx, size_t maxlen,
						 unsigned long value, bool negative, unsigned long base, unsigned int prec,
						 unsigned int width, unsigned int flags)
{
	char buf[PRINTF_NTOA_BUFFER_SIZE];
	size_t len = 0U;

	// no hash for 0 values
	if(!value)
	{
		flags &= ~FLAGS_HASH;
	}

	// write if precision != 0 and value is != 0
	if(!(flags & FLAGS_PRECISION) || value)
	{
		do
		{
			const char digit = (char)(value % base);
			buf[len++] =
				digit < 10 ? '0' + digit : (flags & FLAGS_UPPERCASE ? 'A' : 'a') + digit - 10;
			value /= base;
		} while(value && (len < PRINTF_NTOA_BUFFER_SIZE));
	}

	return _ntoa_format(out, buffer, idx, maxlen, buf, len, negative, (unsigned int)base, prec,
						width, flags);
}

// internal itoa for 'long long' type
#if defined(PRINTF_SUPPORT_LONG_LONG)
static size_t _ntoa_long_long(out_fct_type out, char* buffer, size_t idx, size_t maxlen,
							  unsigned long long value, bool negative, unsigned long long base,
							  unsigned int prec, unsigned int width, unsigned int flags)
{
	char buf[PRINTF_NTOA_BUFFER_SIZE];
	size_t len = 0U;

	// no hash for 0 values
	if(!value)
	{
		flags &= ~FLAGS_HASH;
	}

	// write if precision != 0 and value is != 0
	if(!(flags & FLAGS_PRECISION) || value)
	{
		do
		{
			const char digit = (char)(value % base);
			buf[len++] =
				digit < 10 ? '0' + digit : (flags & FLAGS_UPPERCASE ? 'A' : 'a') + digit - 10;
			value /= base;
		} while(value && (len < PRINTF_NTOA_BUFFER_SIZE));
	}

	return _ntoa_format(out, buffer, idx, maxlen, buf, len, negative, (unsigned int)base, prec,
						width, flags);
}
#endif // PRINTF_SUPPORT_LONG_LONG

#if defined(PRINTF_SUPPORT_FLOAT)

#if defined(PRINTF_SUPPORT_EXPONENTIAL)
// forward declaration so that _ftoa can switch to exp notation for values > PRINTF_MAX_FLOAT
static size_t _etoa(out_fct_type out, char* buffer, size_t idx, size_t maxlen, double value,
					unsigned int prec, unsigned int width, unsigned int flags);
#endif

// internal ftoa for fixed decimal floating point
static size_t _ftoa(out_fct_type out, char* buffer, size_t idx, size_t maxlen, double value,
					unsigned int prec, unsigned int width, unsigned int flags)
{
	char buf[PRINTF_FTOA_BUFFER_SIZE];
	size_t len = 0U;
	double diff = 0.0;

	// powers of 10
	static const double pow10[] = {1,	   10,		100,	  1000,		 10000,
								   100000, 1000000, 10000000, 100000000, 1000000000};

	// test for special values
	if(value != value)
		return _out_rev(out, buffer, idx, maxlen, "nan", 3, width, flags);
	if(value < -DBL_MAX)
		return _out_rev(out, buffer, idx, maxlen, "fni-", 4, width, flags);
	if(value > DBL_MAX)
		return _out_rev(out, buffer, idx, maxlen, (flags & FLAGS_PLUS) ? "fni+" : "fni",
						(flags & FLAGS_PLUS) ? 4U : 3U, width, flags);

	// test for very large values
	// standard printf behavior is to print EVERY whole number digit -- which could be 100s of
	// characters overflowing your buffers == bad
	if((value > PRINTF_MAX_FLOAT) || (value < -PRINTF_MAX_FLOAT))
	{
#if defined(PRINTF_SUPPORT_EXPONENTIAL)
		return _etoa(out, buffer, idx, maxlen, value, prec, width, flags);
#else
		return 0U;
#endif
	}

	// test for negative
	bool negative = false;
	if(value < 0)
	{
		negative = true;
		value = 0 - value;
	}

	// set default precision, if not set explicitly
	if(!(flags & FLAGS_PRECISION))
	{
		prec = PRINTF_DEFAULT_FLOAT_PRECISION;
	}
	// limit precision to 9, cause a prec >= 10 can lead to overflow errors
	while((len < PRINTF_FTOA_BUFFER_SIZE) && (prec > 9U))
	{
		buf[len++] = '0';
		prec--;
	}

	int whole = (int)value;
	double tmp = (value - whole) * pow10[prec];
	unsigned long frac = (unsigned long)tmp;
	diff = tmp - frac;

	if(diff > 0.5)
	{
		++frac;
		// handle rollover, e.g. case 0.99 with prec 1 is 1.0
		if(frac >= pow10[prec])
		{
			frac = 0;
			++whole;
		}
	}
	else if(diff < 0.5)
	{
	}
	else if((frac == 0U) || (frac & 1U))
	{
		// if halfway, round up if odd OR if last digit is 0
		++frac;
	}

	if(prec == 0U)
	{
		diff = value - (double)whole;
		if((!(diff < 0.5) || (diff > 0.5)) && (whole & 1))
		{
			// exactly 0.5 and ODD, then round up
			// 1.5 -> 2, but 2.5 -> 2
			++whole;
		}
	}
	else
	{
		unsigned int count = prec;
		// now do fractional part, as an unsigned number
		while(len < PRINTF_FTOA_BUFFER_SIZE)
		{
			--count;
			buf[len++] = (char)(48U + (frac % 10U));
			if(!(frac /= 10U))
			{
				break;
			}
		}
		// add extra 0s
		while((len < PRINTF_FTOA_BUFFER_SIZE) && (count-- > 0U))
		{
			buf[len++] = '0';
		}
		if(len < PRINTF_FTOA_BUFFER_SIZE)
		{
			// add decimal
			buf[len++] = '.';
		}
	}

	// do whole part, number is reversed
	while(len < PRINTF_FTOA_BUFFER_SIZE)
	{
		buf[len++] = (char)(48 + (whole % 10));
		if(!(whole /= 10))
		{
			break;
		}
	}

	// pad leading zeros
	if(!(flags & FLAGS_LEFT) && (flags & FLAGS_ZEROPAD))
	{
		if(width && (negative || (flags & (FLAGS_PLUS | FLAGS_SPACE))))
		{
			width--;
		}
		while((len < width) && (len < PRINTF_FTOA_BUFFER_SIZE))
		{
			buf[len++] = '0';
		}
	}

	if(len < PRINTF_FTOA_BUFFER_SIZE)
	{
		if(negative)
		{
			buf[len++] = '-';
		}
		else if(flags & FLAGS_PLUS)
		{
			buf[len++] = '+'; // ignore the space if the '+' exists
		}
		else if(flags & FLAGS_SPACE)
		{
			buf[len++] = ' ';
		}
	}

	return _out_rev(out, buffer, idx, maxlen, buf, len, width, flags);
}

#if defined(PRINTF_SUPPORT_EXPONENTIAL)
// internal ftoa variant for exponential floating-point type, contributed by Martijn Jasperse
// <m.jasperse@gmail.com>
static size_t _etoa(out_fct_type out, char* buffer, size_t idx, size_t maxlen, double value,
					unsigned int prec, unsigned int width, unsigned int flags)
{
	// check for NaN and special values
	if((value != value) || (value > DBL_MAX) || (value < -DBL_MAX))
	{
		return _ftoa(out, buffer, idx, maxlen, value, prec, width, flags);
	}

	// determine the sign
	const bool negative = value < 0;
	if(negative)
	{
		value = -value;
	}

	// default precision
	if(!(flags & FLAGS_PRECISION))
	{
		prec = PRINTF_DEFAULT_FLOAT_PRECISION;
	}

	// determine the decimal exponent
	// based on the algorithm by David Gay (https://www.ampl.com/netlib/fp/dtoa.c)
	union
	{
		uint64_t U;
		double F;
	} conv;

	conv.F = value;
	int exp2 = (int)((conv.U >> 52U) & 0x07FFU) - 1023; // effectively log2
	conv.U = (conv.U & ((1ULL << 52U) - 1U)) |
			 (1023ULL << 52U); // drop the exponent so conv.F is now in [1,2)
	// now approximate log10 from the log2 integer part and an expansion of ln around 1.5
	int expval =
		(int)(0.1760912590558 + exp2 * 0.301029995663981 + (conv.F - 1.5) * 0.289529654602168);
	// now we want to compute 10^expval but we want to be sure it won't overflow
	exp2 = (int)(expval * 3.321928094887362 + 0.5);
	const double z = expval * 2.302585092994046 - exp2 * 0.6931471805599453;
	const double z2 = z * z;
	conv.U = (uint64_t)(exp2 + 1023) << 52U;
	// compute exp(z) using continued fractions, see
	// https://en.wikipedia.org/wiki/Exponential_function#Continued_fractions_for_ex
	conv.F *= 1 + 2 * z / (2 - z + (z2 / (6 + (z2 / (10 + z2 / 14)))));
	// correct for rounding errors
	if(value < conv.F)
	{
		expval--;
		conv.F /= 10;
	}

	// the exponent format is "%+03d" and largest value is "307", so set aside 4-5 characters
	unsigned int minwidth = ((expval < 100) && (expval > -100)) ? 4U : 5U;

	// in "%g" mode, "prec" is the number of *significant figures* not decimals
	if(flags & FLAGS_ADAPT_EXP)
	{
		// do we want to fall-back to "%f" mode?
		if((value >= 1e-4) && (value < 1e6))
		{
			if((int)prec > expval)
			{
				prec = (unsigned)((int)prec - expval - 1);
			}
			else
			{
				prec = 0;
			}
			flags |= FLAGS_PRECISION; // make sure _ftoa respects precision
			// no characters in exponent
			minwidth = 0U;
			expval = 0;
		}
		else
		{
			// we use one sigfig for the whole part
			if((prec > 0) && (flags & FLAGS_PRECISION))
			{
				--prec;
			}
		}
	}

	// will everything fit?
	unsigned int fwidth = width;
	if(width > minwidth)
	{
		// we didn't fall-back so subtract the characters required for the exponent
		fwidth -= minwidth;
	}
	else
	{
		// not enough characters, so go back to default sizing
		fwidth = 0U;
	}
	if((flags & FLAGS_LEFT) && minwidth)
	{
		// if we're padding on the right, DON'T pad the floating part
		fwidth = 0U;
	}

	// rescale the float value
	if(expval)
	{
		value /= conv.F;
	}

	// output the floating part
	const size_t start_idx = idx;
	idx = _ftoa(out, buffer, idx, maxlen, negative ? -value : value, prec, fwidth,
				flags & ~FLAGS_ADAPT_EXP);

	// output the exponent part
	if(minwidth)
	{
		// output the exponential symbol
		out((flags & FLAGS_UPPERCASE) ? 'E' : 'e', buffer, idx++, maxlen);
		// output the exponent value
		idx = _ntoa_long(out, buffer, idx, maxlen, (expval < 0) ? -expval : expval, expval < 0, 10,
						 0, minwidth - 1, FLAGS_ZEROPAD | FLAGS_PLUS);
		// might need to right-pad spaces
		if(flags & FLAGS_LEFT)
		{
			while(idx - start_idx < width)
				out(' ', buffer, idx++, maxlen);
		}
	}
	return idx;
}
#endif // PRINTF_SUPPORT_EXPONENTIAL
#endif // PRINTF_SUPPORT_FLOAT

// internal vsnprintf
static int _vsnprintf(out_fct_type out, char* buffer, const size_t maxlen, const char* format,
					  va_list va)
{
	unsigned int flags, width, precision, n;
	size_t idx = 0U;

	if(!buffer)
	{
		// use null output function
		out = _out_null;
	}

	while(*format && idx < maxlen)
	{
		// format specifier?  %[flags][width][.precision][length]
		if(*format != '%')
		{
			// no
			out(*format, buffer, idx++, maxlen);
			format++;
			continue;
		}
		else
		{
			// yes, evaluate it
			format++;
		}

		// evaluate flags
		flags = 0U;
		do
		{
			switch(*format)
			{
				case '0':
					flags |= FLAGS_ZEROPAD;
					format++;
					n = 1U;
					break;
				case '-':
					flags |= FLAGS_LEFT;
					format++;
					n = 1U;
					break;
				case '+':
					flags |= FLAGS_PLUS;
					format++;
					n = 1U;
					break;
				case ' ':
					flags |= FLAGS_SPACE;
					format++;
					n = 1U;
					break;
				case '#':
					flags |= FLAGS_HASH;
					format++;
					n = 1U;
					break;
				default:
					n = 0U;
					break;
			}
		} while(n);

		// evaluate width field
		width = 0U;
		if(_is_digit(*format))
		{
			width = _atoi(&format);
		}
		else if(*format == '*')
		{
			const int w = va_arg(va, int);
			if(w < 0)
			{
				flags |= FLAGS_LEFT; // reverse padding
				width = (unsigned int)-w;
			}
			else
			{
				width = (unsigned int)w;
			}
			format++;
		}

		// evaluate precision field
		precision = 0U;
		if(*format == '.')
		{
			flags |= FLAGS_PRECISION;
			format++;
			if(_is_digit(*format))
			{
				precision = _atoi(&format);
			}
			else if(*format == '*')
			{
				const int prec = (int)va_arg(va, int);
				precision = prec > 0 ? (unsigned int)prec : 0U;
				format++;
			}
		}

		// evaluate length field
		switch(*format)
		{
			case 'l':
				flags |= FLAGS_LONG;
				format++;
				if(*format == 'l')
				{
					flags |= FLAGS_LONG_LONG;
					format++;
				}
				break;
			case 'h':
				flags |= FLAGS_SHORT;
				format++;
				if(*format == 'h')
				{
					flags |= FLAGS_CHAR;
					format++;
				}
				break;
#if defined(PRINTF_SUPPORT_PTRDIFF_T)
			case 't':
				flags |= (sizeof(ptrdiff_t) == sizeof(long) ? FLAGS_LONG : FLAGS_LONG_LONG);
				format++;
				break;
#endif
			case 'j':
				flags |= (sizeof(intmax_t) == sizeof(long) ? FLAGS_LONG : FLAGS_LONG_LONG);
				format++;
				break;
			case 'z':
				flags |= (sizeof(size_t) == sizeof(long) ? FLAGS_LONG : FLAGS_LONG_LONG);
				format++;
				break;
			default:
				break;
		}

		// evaluate specifier
		switch(*format)
		{
			case 'd':
			case 'i':
			case 'u':
			case 'x':
			case 'X':
			case 'o':
			case 'b': {
				// set the base
				unsigned int base;
				if(*format == 'x' || *format == 'X')
				{
					base = 16U;
				}
				else if(*format == 'o')
				{
					base = 8U;
				}
				else if(*format == 'b')
				{
					base = 2U;
				}
				else
				{
					base = 10U;
					flags &= ~FLAGS_HASH; // no hash for dec format
				}
				// uppercase
				if(*format == 'X')
				{
					flags |= FLAGS_UPPERCASE;
				}

				// no plus or space flag for u, x, X, o, b
				if((*format != 'i') && (*format != 'd'))
				{
					flags &= ~(FLAGS_PLUS | FLAGS_SPACE);
				}

				// ignore '0' flag when precision is given
				if(flags & FLAGS_PRECISION)
				{
					flags &= ~FLAGS_ZEROPAD;
				}

				// convert the integer
				if((*format == 'i') || (*format == 'd'))
				{
					// signed
					if(flags & FLAGS_LONG_LONG)
					{
#if defined(PRINTF_SUPPORT_LONG_LONG)
						const long long value = va_arg(va, long long);
						idx = _ntoa_long_long(out, buffer, idx, maxlen,
											  (unsigned long long)(value > 0 ? value : 0 - value),
											  value < 0, base, precision, width, flags);
#endif
					}
					else if(flags & FLAGS_LONG)
					{
						const long value = va_arg(va, long);
						idx = _ntoa_long(out, buffer, idx, maxlen,
										 (unsigned long)(value > 0 ? value : 0 - value), value < 0,
										 base, precision, width, flags);
					}
					else
					{
						const int value = (flags & FLAGS_CHAR)	  ? (char)va_arg(va, int)
										  : (flags & FLAGS_SHORT) ? (short int)va_arg(va, int)
																  : va_arg(va, int);
						idx = _ntoa_long(out, buffer, idx, maxlen,
										 (unsigned int)(value > 0 ? value : 0 - value), value < 0,
										 base, precision, width, flags);
					}
				}
				else
				{
					// unsigned
					if(flags & FLAGS_LONG_LONG)
					{
#if defined(PRINTF_SUPPORT_LONG_LONG)
						idx = _ntoa_long_long(out, buffer, idx, maxlen,
											  va_arg(va, unsigned long long), false, base,
											  precision, width, flags);
#endif
					}
					else if(flags & FLAGS_LONG)
					{
						idx = _ntoa_long(out, buffer, idx, maxlen, va_arg(va, unsigned long), false,
										 base, precision, width, flags);
					}
					else
					{
						const unsigned int value =
							(flags & FLAGS_CHAR)	? (unsigned char)va_arg(va, unsigned int)
							: (flags & FLAGS_SHORT) ? (unsigned short int)va_arg(va, unsigned int)
													: va_arg(va, unsigned int);
						idx = _ntoa_long(out, buffer, idx, maxlen, value, false, base, precision,
										 width, flags);
					}
				}
				format++;
				break;
			}
#if defined(PRINTF_SUPPORT_FLOAT)
			case 'f':
			case 'F':
				if(*format == 'F')
					flags |= FLAGS_UPPERCASE;
				idx = _ftoa(out, buffer, idx, maxlen, va_arg(va, double), precision, width, flags);
				format++;
				break;
#if defined(PRINTF_SUPPORT_EXPONENTIAL)
			case 'e':
			case 'E':
			case 'g':
			case 'G':
				if((*format == 'g') || (*format == 'G'))
					flags |= FLAGS_ADAPT_EXP;
				if((*format == 'E') || (*format == 'G'))
					flags |= FLAGS_UPPERCASE;
				idx = _etoa(out, buffer, idx, maxlen, va_arg(va, double), precision, width, flags);
				format++;
				break;
#endif // PRINTF_SUPPORT_EXPONENTIAL
#endif // PRINTF_SUPPORT_FLOAT
#ifndef PRINTF_DISABLE_CHAR_FORMAT
			case 'c': {
				unsigned int l = 1U;
				// pre padding
				if(!(flags & FLAGS_LEFT))
				{
					while(l++ < width)
					{
						out(' ', buffer, idx++, maxlen);
					}
				}
				// char output
				out((char)va_arg(va, int), buffer, idx++, maxlen);
				// post padding
				if(flags & FLAGS_LEFT)
				{
					while(l++ < width)
					{
						out(' ', buffer, idx++, maxlen);
					}
				}
				format++;
				break;
			}
#endif
			case 's': {
				const char* p = va_arg(va, char*);
				unsigned int l = _strnlen_s(p, precision ? precision : (size_t)256);
				// pre padding
				if(flags & FLAGS_PRECISION)
				{
					l = (l < precision ? l : precision);
				}
				if(!(flags & FLAGS_LEFT))
				{
					while(l++ < width)
					{
						out(' ', buffer, idx++, maxlen);
					}
				}
				// string output
				while((*p != 0) && (!(flags & FLAGS_PRECISION) || precision--) && idx < maxlen)
				{
					out(*(p++), buffer, idx++, maxlen);
				}
				// post padding
				if(flags & FLAGS_LEFT)
				{
					while(l++ < width)
					{
						out(' ', buffer, idx++, maxlen);
					}
				}
				format++;
				break;
			}
#ifndef PRINTF_DISABLE_CHAR_FORMAT
			case 'p': {
				width = sizeof(void*) * 2U;
				flags |= FLAGS_ZEROPAD | FLAGS_UPPERCASE;
#if defined(PRINTF_SUPPORT_LONG_LONG)
				const bool is_ll = sizeof(uintptr_t) == sizeof(long long);
				if(is_ll)
				{
					idx = _ntoa_long_long(out, buffer, idx, maxlen, (uintptr_t)va_arg(va, void*),
										  false, 16U, precision, width, flags);
				}
				else
				{
#endif
					idx = _ntoa_long(out, buffer, idx, maxlen,
									 (unsigned long)((uintptr_t)va_arg(va, void*)), false, 16U,
									 precision, width, flags);
#if defined(PRINTF_SUPPORT_LONG_LONG)
				}
#endif
				format++;
				break;
			}
#endif
			case '%':
				out('%', buffer, idx++, maxlen);
				format++;
				break;

			default:
				out(*format, buffer, idx++, maxlen);
				format++;
				break;
		}
	}

	// termination
	out((char)0, buffer, idx < maxlen ? idx : maxlen - 1U, maxlen);

	// return written chars without terminating \0
	return (int)idx;
}

///////////////////////////////////////////////////////////////////////////////

int printf_(const char* format, ...)
{
	va_list va;
	va_start(va, format);
	char buffer[1];
	const int ret = _vsnprintf(_out_char, buffer, (size_t)1, format, va);
	va_end(va);
	return ret;
}

int sprintf_(char* buffer, const char* format, ...)
{
	va_list va;
	va_start(va, format);
	const int ret = _vsnprintf(_out_buffer, buffer, (size_t)256, format, va);
	va_end(va);
	return ret;
}

int snprintf_(char* buffer, size_t count, const char* format, ...)
{
	va_list va;
	va_start(va, format);
	const int ret = _vsnprintf(_out_buffer, buffer, count, format, va);
	va_end(va);
	return ret;
}

int vprintf_(const char* format, va_list va)
{
	char buffer[1];
	return _vsnprintf(_out_char, buffer, (size_t)1, format, va);
}

int vsnprintf_(char* buffer, size_t count, const char* format, va_list va)
{
	return _vsnprintf(_out_buffer, buffer, count, format, va);
}

int fctprintf(void (*out)(char character, void* arg), void* arg, const char* format, ...)
{
	va_list va;
	va_start(va, format);
	const out_fct_wrap_type out_fct_wrap = {out, arg};
	const int ret = _vsnprintf(_out_fct, (char*)(uintptr_t)&out_fct_wrap, (size_t)128, format, va);
	va_end(va);
	return ret;
}
